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802.11n Primer
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2. 802.11n Primer
Introduction
In less than a decade, wireless LANs have evolved from a niche technology useable
only by a few specialized applications to the default media of choice for millions of
businesses and consumers. And WLANs continue to evolve. The latest generation of
high-speed wireless LAN technology, based on the Institute of Electrical and
Electronics Engineers (IEEE) Draft 802.11n standard, are now becoming available.
The technology behind 802.11n is projected to deliver as much as a six fold increase
in effective bandwidth, as well as increased WLAN reliability compared to existing
802.11g and 802.11a deployments. The promise of 802.11n has led some to consider
the wireless LAN as a viable alternative to the wired network.
At a minimum, the advances realized by 802.11n will cause many enterprises to
reconsider the role of WLANs in their network, as well as the effect of such a
deployment on their infrastructure. Before deploying 802.11n, however, organizations
will need to understand the answers to some basic questions, including:
• What do 802.11n technologies do differently than existing WLAN elements?
• Is 802.11n backward-compatible with my existing wired and wireless network
design?
• What modes can the deployed?
While these questions are simple, the answers to them are not. 802.11n utilizes some
very complex technologies, some more frequently used in the worlds of
radio/broadcast than in networking. Indeed, there is no shortage of white papers
claiming to “demystify” 802.11n but only succeeding in introducing a plethora of new
four letter acronyms.
In this paper, we will look at the basic elements of 802.11n functionality, with an
emphasis on how it differs from WLAN technologies in use today. Our primary focus
will be on the major methods that 802.11n uses to deliver on the claim of large
increases in throughput and reliability.
The Basis of 802.11n Performance and Reliability
802.11n touts major improvements in both performance and reliability, yet also
purports to have backward compatibility with 802.11a and 802.11b/g equipment.
802.11n realizes backward compatibility, higher performance and increased
reliability through the action and interaction of two key technologies:
• Multiple In/Multiple Out (MIMO) transmit/receive capabilities
• Channel Bonding.
Incremental improvements are also seen by combining a myriad of additional
technologies, but for the sake of simplicity, we will consider only the primary changes
in this paper.
2 Copyright ©2011, Aerohive Networks, Inc.
3. Multiple In, Multiple Out (MIMO)
MIMO is the biggest innovation that comes along with 802.11n. Though there are
different kinds of MIMO techniques, we will limit our discussion to the most useful and
prevalent form in building enterprise WLANs, often called “spatial diversity MIMO” or
“multipath MIMO”.
Multiple In
When you only use one antenna on the transmitter and one receiver in an indoor
environment, you are subject to “multipath” interference. Multipath interference
happens when a number of packets are encoded and sent out over the air. The
waveform will interact with anything it encounters on its way from transmitter to
receiver. Some of these things, like a metal fire door, will reflect the signal; some
things, like a working microwave, will interfere with it; some things, like organic
material such as plants and people, will absorb it. The result is that the receiver can
end up with multiple copies of the original signal. This is similar to how a single sound
produced in a canyon can result in an echo, sounding to the listener like the sound is
produced many times over, out of phase with the original. This echo effect makes it
difficult to sort out the original message, since signals received in different phases can
combine or even completely cancel one another. We have all encountered this
effect when listening to the radio in the car. The signal might be just fine until you
come to a particular place, like a stop light, where suddenly the signal seems to
disappear. If you move a bit, however, the signal comes back. What is really
happening when the radio station appears to go away is that multipath interference
is creating a null – the signals received are offset from each other and, when
combined net a zero signal. When you move, you’ve shifted what the receiver
“hears,” and the signal appears to come back. With a complex signal, it can be
virtually impossible to determine where one message ends and another begins.
One way that WLAN providers have
worked around multipath is to provide
a diverse set of antennas. Antenna
diversity, however, is not MIMO. Only
one of the set of antennas are
actually transmitting or receiving – the
WLAN is just able to select the one
antenna with the best signal-to-noise
ratio.
Multipath has traditionally been the
enemy of WLANs, because the echo-
like effect typically serves to detract
from the original signal. When using
MIMO and its multiple receiving
antennas, however, the effects of
multipath become additive – that is, multiple messages can be received by multiple
antennas, and combined. When using MIMO, we still get multipath as always, but this
time we can sort out a message more easily and actually use the multipath
reflections to our advantage to gain significant signal strength and thus improve
reliability. What does more
reliability get you? Reliability Figure 1. Multipath use for 802.11a/b/g vs. 802.11n
Copyright ©2011, Aerohive Networks, Inc. 3
4. 802.11n Primer
translates to a greater coverage area for a given data rate or to higher data rates
for a given coverage area. That translates to more bandwidth per user.
Multiple Out
MIMO allows for multiple (from 2 to 4) transmitting and receiving antennas that
operate simultaneously. Using advanced signal processing on both access points
and clients, MIMO transmitters can multiplex a message over separate transmitting
antennas. The receivers leverage digital signal processing to identify separate bit
streams, commonly known as spatial streams, and re-assemble them. This multiplexing
dramatically increases the effective bandwidth.
Thus the two biggest improvements MIMO brings are:
• The ability to more easily sort out multipath echoes which increases reliability
(and as shown, more reliability = more bandwidth per user)
• The ability to multiplex different data streams across multiple transmitters
which increases effective bandwidth.
MIMO APs With Legacy Clients
MIMO can also help reliability for legacy 802.11b/g and 802.11a clients. This is
because in 802.11a/b/g APs cope with multipath interference by scaling back the
data rate. This means that clients that could get 54 Mbps throughput in an
interference-free environment might have to drop to 48 or 36 Mbps at a short
distance from the AP in the presence of multipath. Even if MIMO is used only in the
access points, the technology still delivers up to a thirty percent performance
enhancement over conventional 802.11a/b/g networks, because of the fact that
MIMO receive antenna technology handles multipath in a much better way. This
efficiency means that clients that would normally have to drop from 54 Mbps data
rates to 48 or 36 Mbps at a short distance from the AP can now remain associated at
54 Mbps.
MIMO Transmitter and Receiver Options
The 802.11n standard allows for several different configurations of transmitters and
receivers, from 2 to 4 transmitters and from 1 to 4 receivers. MIMO systems are
described by quoting the number of transmitters “by” the number of receivers. Thus a
“2x1” system has two transmitters and 1 receiver. Adding transmitters or receivers to
the system will increase performance, but only to a point. For example, it is generally
accepted that the benefits are large for each step from 2x1 to 2x2 and from 2x3 to
3x3, but beyond that the value is diminished for the current generation of 802.11n.
Additionally it is often recommended that access points are optimized in a 3x3
configuration whereas clients function best in a 2x3 configuration. 1 The AP can make
use of the additional transmitter because it is handling multiple clients.
1 See “MIMO Architecture, the power of 3” Atheros Communications Inc. Winston Sun, Ph.d.
http://www.atheros.com/pt/whitepapers/MIMO_Pwr3_whitepaper.pdf
4 Copyright ©2011, Aerohive Networks, Inc.
5. Channel Bonding
Channel bonding is a technique where two adjacent contiguous 20MHz channels
are combined into a wider 40MHz channel. In fact, the bandwidth on both edges of
a 20MHz channel are typically not utilized at 100%, in order to prevent any channel
overlap. Channel bonding allows the use of both 20 MHz channels as well as this gap
between the channels, resulting slightly more than double the bandwidth. For
example, the highest data rate for 802.11a or 802.11g is 54 Mbps for a single
transmitter on a 20MHz channel. In 802.11n, a 20 MHz wide channel was made more
efficient using various incremental improvements to increase the maximum data rate
of a single channel from 54 to 65 Mbps.
Figure 2. Four 5GHz 20 MHz channels
With the addition of channel bonding and better spectral efficiency, a 40MHz
bonded channel on a single transmitter gets you slightly more than double the 54
Mbps data rate, or 135 Mbps.
Figure 3. Four 5GHz 20 MHz channels bonded to form two 40 MHz channels
The drawback to channel bonding, as we’ll show in a minute, is that it can really only
be implemented in the 5 GHz band.
Copyright ©2011, Aerohive Networks, Inc. 5
6. 802.11n Primer
Channel Usage
802.11n can operate in either the 2.4 (802.11b/g) or 5 GHz (802.11a) ranges. If you
have an access point with two 802.11n radios, it can operate in both 2.4 GHz and 5
GHz bands simultaneously. The access point can be configured to use the same
channels as 802.11b/g and 802.11a, and thus remain backward compatible with
clients still running 802.11b/g or 802.11a.
When building a wireless LAN for the enterprise, it is important that no two APs
operate on the same channel when they are in close proximity. Doing so causes ‘co-
channel interference’ and is similar to having two radio stations transmit on the same
frequency, in that the receiver ends up getting mostly garbage. To avoid this, the APs
need to change the channels they use so as to not interfere with each other. That
can get tricky if there aren’t enough channels to choose from. 802.11 b/g in the 2.4
GHz range has a three to one reuse pattern for useable channels. This three to one
pattern is the very minimum number that can be used to build a non-interfering
network.
So what happens with 802.11n when you introduce things like an increased range
and channel bonding? It becomes clear that the 5GHz band is the only choice when
using 802.11n with channel bonding, as it easily allows enough 20MHz non-interfering
channels to get to a seven to one reuse pattern and a three to one reuse pattern
with 40 MHz channels. This allows plenty of spectrum for building out a WLAN without
co-channel interference.
Figure 4. Reuse pattern for 5GHz Figure 5. Reuse pattern for 2.4GHz
using 20MHz channels using 20MHz channels
6 Copyright ©2011, Aerohive Networks, Inc.
7. Maximum Data Rates for .11n
Several factors determine the maximum performance that can be achieved with
802.11n. Spatial streams and channel bonding that were mentioned earlier provide the
biggest benefits, but there are several other items that can also increase performance.
Short Guard interval (GI)
A guard interval is a set amount of time between transmissions, designed to ensure that
distinct transmissions do not interfere with one another. The purpose of the guard interval
is to introduce immunity to propagation delays, echoes and reflections. The shorter the
guard interval, the more efficiency there is in the channel usage but a shorter guard
interval also increases the risk of interference.
A short guard interval of 400 nanoseconds (ns) will work in most office environments since
distances between points of reflection, as well as between clients, are short. Most
reflections will be received quickly, within 50-100 ns. The need for a long guard interval of
800 ns becomes more important as areas become larger, such as in warehouses and in
outdoor environments, as reflections and echoes become more likely to continue after
the short guard interval would be over.
The guard interval that was set in 802.11 specifications prior to 802.11n was longer than
was needed in many environments. A shorter guard interval was added as an option in
the 802.11n specification to allow for higher data rates where a long guard interval is not
required.
Frame Aggregation
Data over wired and wireless networks are sent as a stream of packets known as data
frames. Frame aggregation takes these packets and combines them into fewer, larger
packets allowing an increase in overall performance. This was added to the 802.11n
specification to allow for an additional increase in performance.
Frame aggregation is a feature that only 802.11n clients can take advantage of since
legacy clients will not be able to understand the new format of the larger packets.
Reduced Inter-Frame Spacing (RIFS)
The standard spacing between 802.11 packets are known as Short Inter-frame Space
(SIFS). 802.11n adds a smaller spacing between the packets when a larger spacing isn’t
required. This reduces the overhead and increases throughput slightly. This was added to
the 802.11n specification to increase performance where possible.
RIFS is a feature that only 802.11n clients can take advantage of since legacy clients will
not be able to receive packets with the shorter spacing.
Listed in the table below are the maximum possible data rates when using 802.11n
with and without channel bonding, using one through four theoretical spatial
streams, with both long and short guard intervals.
Copyright ©2011, Aerohive Networks, Inc. 7
8. 802.11n Primer
Table 2. 802.11n Performance
Of particular note is that:
• Today’s radio chipsets generally do not support more than 2 spatial streams,
nor do they support a true “greenfield” configuration.
• The data rate describes the phy-level encoding rate over the air which has
significant overhead. The actual wired bandwidth throughput is roughly 50%
of the data rate.
One simple conclusion is that we will see future generations of chipsets capable of
even higher bandwidths than exist today.
Backward Compatibility
An 802.11n AP is backward compatible with legacy 802.11b/g (2.4 GHz) or 802.11a (5
GHz) clients. Please note, however, that there is a performance tradeoff in this
configuration, similar to that observed with an 802.11g AP supporting 802.11b clients.
• Though legacy clients will benefit somewhat from the extended range an
802.11n AP can offer, they are not capable of the higher data rates.
• A .11g client takes longer to send a given amount of data when compared to
a .11n client, therefore the .11g client will consume more “air time.” This has
the impact of limiting the air time available to .11n clients which in a
congested state will reduce 802.11n performance.
Compatibility modes of .11n
An 802.11n access point can be configured to operate in three modes; Legacy,
Mixed and Greenfield Modes.
8 Copyright ©2011, Aerohive Networks, Inc.
9. Legacy mode
In this mode, the access point is configured to operate just like an 802.11a or 802.11g
device. No benefits of 802.11n such as MIMO or channel bonding are utilized. This
mode could be used when an enterprise buys a new 802.11n access point and,
although some laptops may have .11n capabilities, the company chooses
consistency among user experience over maximum possible speed. In Legacy mode,
802.11n capabilities exist, but are not turned on.
Mixed mode
This mode will be the most popular of the possible deployments. In this mode the
access point is configured to operate as an 802.11n AP while also communicating
with 802.11 a/b/g stations. When configured for mixed mode, the 802.11n access
point must provide ‘protection’ for the older 802.11 devices, in much the same way
that 802.11g access points would communicate with 802.11b clients. Thus the
presence of an 802.11a/g client reduces the overall bandwidth capacity of the
802.11n access point, in part because of the lower data rates at which the a/g clients
communicate.
Greenfield mode
This mode is described in the standard and assumes that only 802.11n stations
operate on the network, with no protection mechanisms for 802.11 a/b/g necessary.
Most current 802.11n chipsets do not support this mode, as the incremental
performance benefit is small and it is expected that mixed mode will be prevalent for
the near future.
802.11n – the WLAN for the Future
802.11n provides significant improvements in WLAN performance and reliability for
802.11n clients, as well as performance and reliability improvements to existing
legacy clients. MIMO takes the challenge of multipath interference and uses it to
increase performance and reliability of the overall network. The addition of channel
bonding can realize significant benefits in performance as well.
The combination of these innovative features allows immediate advantages to be
seen when migrating to a 802.11n wireless network even with legacy clients. The
benefits only increase as more clients become 802.11n capable over time.
The increase of performance, throughput, and reliability of 802.11n allows the WLAN
to become a viable alternative/companion to the wired network for high bandwidth
and mission-critical applications.
Copyright ©2011, Aerohive Networks, Inc. 9
10. About Aerohive
Aerohive Networks reduces the cost and complexity of todayÕ s networks with cloud-
enabled, distributed Wi-Fi and routing solutions for enterprises and medium sized
companies including branch offices and teleworkers. AerohiveÕ s award-winning
cooperative control Wi-Fi architecture, public or private cloud-enabled network
management, routing and VPN solutions eliminate costly controllers and single points of
failure. This gives its customers mission critical reliability with granular security and policy
enforcement and the ability to start small and expand without limitations. Aerohive was
founded in 2006 and is headquartered in Sunnyvale, Calif. The companyÕ s investors
include Kleiner Perkins Caufield & Byers, Lightspeed Venture Partners, Northern Light
Venture Capital and New Enterprise Associates, Inc. (NEA).
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